RU2536167C2 - Drive mechanism for medium voltage fuse switches - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention refers to a drive mechanism. A drive mechanism for a medium voltage fuse switch comprises a base plate (10) and a front plate (11) which form an inner space enveloping a working shaft and a driving shaft set coaxially along the first longitudinal axis, the driving shaft is functionally coupled with a kinematic circuit of the medium voltage fuse switch, the working shaft (20) is fitted by a head connected to an operating handle for manual actuation of the working shaft, a spring unit consisting of two spiral springs having the first end functionally coupled with the working shaft, a clamping unit consisting of two clamping tabs set on the driving shaft, the first (61) and the second (62) unclamping units to unclamp the driving shaft and provide for its rotation. The first unclamping unit (61) provides for the rotation of the driving shaft in the direction opposite to the second unclamping unit (62).

EFFECT: reduced manufacturing, mounting and operational costs.

11 cl, 8 dwg

Description

The present invention relates to a drive mechanism for a medium voltage circuit breaker, in particular, a drive mechanism for a medium voltage circuit breaker switch having advanced features. For the purposes of this application, the term medium voltage refers to applications ranging from 1 to 52 kV.

Medium voltage circuit breakers, in particular medium circuit breaker circuit breakers, are well known in the art and typically include a drive mechanism that is connected to the kinematic circuit of the circuit breaker and acts on it to open and close the circuit breaker contacts. For the speed required to perform the opening / closing operation, mechanical means are typically used to actuate the kinematic circuit of the circuit breaker. In most cases, the drive mechanisms are based on springs that are loaded before the opening / closing operation; when the spring is opened, the drive mechanism transfers the energy and movement created by the spring to the kinematic circuit of the switch, whereby the opening / closing operation is performed with the required speed. In a mechanism of a known type, the operation is usually performed by an operator acting on the control handle, which is used to load the spring and perform the operation of expanding the spring itself, whereby the opening / closing operation is completed.

No. 4,683,357 A discloses a drive mechanism for a medium voltage fuse switch, comprising:

- the base plate and the front plate, forming the inner space containing the working shaft and the drive shaft, coaxially mounted along the first longitudinal axis, while the drive shaft is configured to connect to the kinematic circuit of the circuit breaker with a medium voltage fuse for the operation of opening / closing the switch, this working shaft has a head connected to the control handle for manually actuating the working shaft;

- the spring assembly, which contains the first and second coil springs having a first end connected to the working shaft, while the coil springs are made to be loaded by turning the working shaft and actuating the drive shaft during expansion, while the first coil spring is made with the ability to rotate the drive shaft in the opposite direction relative to the rotation specified by the second coil spring;

- clamping means for clamping the drive shaft, containing the first and second clamping tabs located on the drive shaft;

- first and second expansion means for expanding the drive shaft and allowing it to be rotated, while the first expansion means is configured to rotate the drive shaft in the opposite direction relative to the second expansion means.

Although the currently known drive mechanisms are undoubtedly suitable for controlling the opening / closing operation of a medium voltage circuit breaker, they are not entirely satisfactory in terms of operational quality and / or manufacturing cost.

In particular, in the case of a drive mechanism for medium voltage fuse switches, it would be desirable to have a simpler alternative to the existing system.

An additional problem arises due to the speed requirements of the opening / closing operation of the circuit breaker, which includes the precise sizing of the spring, as well as its thorough testing.

Also, the characteristics of the spring can change during the service life, whereby also reducing the speed characteristics of the associated switch to values that are no longer valid.

Therefore, it is an object of the present invention to provide a drive mechanism for a medium voltage circuit breaker, in particular a drive mechanism for a medium voltage circuit breaker, in which the aforementioned disadvantages are eliminated or at least reduced.

An additional objective of the present invention is to provide a drive mechanism for a medium voltage circuit breaker that does not require excessive dimensional accuracy and preliminary testing of the spring.

Another objective of the present invention is to provide a drive mechanism for a medium voltage circuit breaker, which makes it possible to adjust the characteristics of the spring and its adaptation for use in a simple manner.

An additional objective of the present invention is to provide a drive mechanism for a medium voltage circuit breaker that is simply adaptable for various applications.

Another objective of the present invention is to provide a drive mechanism for a medium voltage circuit breaker with reduced production, installation and operating costs.

Thus, the present invention relates to a drive mechanism for a medium voltage fuse switch, which is characterized in that it comprises:

- the base plate and the front plate, forming the inner space containing the working shaft and the drive shaft, coaxially mounted along the first longitudinal axis, while the drive shaft is configured to connect to the kinematic circuit of the circuit breaker with a medium voltage fuse for the operation of opening / closing the switch, this working shaft has a head connected to the control handle for manually actuating the working shaft;

- the spring assembly, which contains the first and second coil springs having a first end connected to the working shaft, while the coil springs are made to be loaded by turning the working shaft and actuating the drive shaft during expansion, while the first coil spring is made with the ability to rotate the drive shaft in the opposite direction relative to the rotation specified by the second coil spring;

- clamping means for clamping the drive shaft, containing the first and second clamping tabs located on the drive shaft;

- first and second expansion means for expanding the drive shaft and allowing it to rotate, while the first expansion means is configured to rotate the drive shaft in the opposite direction relative to the second expansion means, wherein the working shaft comprises a first subassembly containing a disk perpendicular to the first a longitudinal axis, and further comprising a first plate element protruding perpendicularly from the edge of the disk in the direction of the working head its shaft.

Due to the presence of clamping and expanding means, the drive mechanism for the medium voltage circuit breaker according to the invention allows the opening and closing operation to be carried out very simply and efficiently, as best explained in the following detailed description of preferred embodiments of the invention.

A medium voltage switch comprising a drive mechanism as described above is also part of the present invention.

Additional characteristics and advantages of the invention will be apparent from the description of preferred, but non-exclusive embodiments of the drive mechanism for a medium voltage fuse switch according to the invention, non-exclusive examples of which are provided in the accompanying drawings, in which:

FIG. 1 is a perspective front view of a possible embodiment of a drive mechanism in accordance with the invention;

FIG. 2 is a perspective rear view of a possible embodiment of a drive mechanism in accordance with the invention;

FIG. 3 is a top view of an embodiment of a working shaft, a drive shaft, and a spring assembly used in a drive mechanism in accordance with the invention;

FIG. 4 is an exploded view of the assembly of FIG. 3;

FIG. 5 is a rear view of a drive mechanism in accordance with the invention, with clamping and expanding means in a first operating position;

FIG. 6 is a rear view of the drive mechanism of FIG. 5, with clamping and expanding means in a second operating position;

FIG. 7 is a rear view of the drive mechanism of FIG. 5, with clamping and expanding means in a third operating position;

FIG. 8 is a rear view of the drive mechanism of FIG. 5, with clamping and expanding means in a fourth operating position.

With reference to the accompanying figures, the drive mechanism for a medium voltage fuse switch in accordance with the invention, generally indicated by reference numeral 1, typically comprises a base plate 10 and a front plate 11 that form an interior space. Additional plates, for example plate 13, may also occur between the front 11 and base 10 plate. The drive mechanism also contains a number of constituent elements for connecting it to a medium voltage switch, which may be of a traditional type and which will not be described in detail.

The working shaft 2 and the drive shaft 3 are placed in the indicated internal space and coaxially mounted along the first longitudinal axis, while the drive shaft 3 is connected to the kinematic circuit of a medium-voltage fuse switch by means of a traditional connecting system for performing the opening / closing operation of the switch. The working shaft 2 has a head 20 connected to the control handle for manually actuating the specified working shaft through an opening located on the front plate 11 of the drive mechanism 1.

The drive mechanism 1 of the invention further comprises a spring assembly 4, which comprises a first 41 and a second 42 coil springs, also located in the inner space between the base plate 10 and the front plate 11.

The first and second coil springs 41 and 42, respectively, have first ends 411 and 421 that are connected to the specified working shaft 2, and a second end 412 connected to the drive shaft 3. The first and second coil springs 41, 42 are loaded by turning the working shaft 2 and drive the drive shaft 3 during expansion, while the first coil spring 41 sets the rotation of the drive shaft 3 in the opposite direction relative to the rotation specified by the second coil spring 42.

One of the distinguishing features of the drive mechanism 1 in accordance with the invention is that it is provided with clamping means 5 for clamping the drive shaft 3, while the clamping means comprises first 51 and second 52 clamping tabs, which are located on the specified drive shaft 3.

Additional features of the drive mechanism 1 in accordance with the invention are that it is also provided with first 61 and second 62 release means for expanding the drive shaft 3 and allowing it to rotate; in particular, as is better explained hereinafter, the first expanding means 61 allows the drive shaft 3 to rotate in a direction that is opposite to the rotation provided by the second expanding means 62.

In fact, the closing operation is performed by loading one of the first or second coil springs 41 and 42, for example a coil spring 41; as soon as the spring is loaded, the drive shaft is clamped by the clamping means 5. Under these conditions, the closing spring is loaded as soon as the drive shaft 3 is clamped to the position corresponding to the open position of the contacts of the associated fuse switch. The closing operation is performed by acting on one of the said expansion means, for example, expansion means 61, whereby by expanding the drive shaft 3 and allowing said drive shaft 3 to rotate in a first direction, for example, clockwise relative to the front view of the drive mechanism 1.

Accordingly, the opening operation is performed by loading another one of said first or second coil springs 41 and 42, for example, coil spring 42; as soon as the spring is loaded, the drive shaft is clamped by the specified clamping means 5. Under these conditions, the opening spring is loaded as soon as the drive shaft 3 is clamped to the position corresponding to the closed position of the contacts of the associated fuse switch. The opening operation is performed by acting on one of the said expanding means, for example, the expanding means 62, whereby the drive shaft 3 is expanded, and it is possible to rotate the specified drive shaft 3 in a second direction, which is opposite to the rotation provided by said second first expansion means 61 for example, in this case, counterclockwise relative to the front view of the drive mechanism 1.

The loading of coil springs 41 and 42 is traditionally performed simultaneously; the closing operation in this case is performed by acting, for example, on the expanding means 61, while the opening operation, respectively, is performed by acting on the expanding means 62.

With reference to FIG. 3 and 4, in the drive mechanism 1 in accordance with the invention, the working shaft 2 preferably comprises a first assembly 21, which, in turn, comprises a disk 22 of a substantially circular shape that is mounted perpendicular to said first longitudinal axis, and further contains the first plate element 23, which protrudes perpendicularly from the edge of the disk 22 in the direction of the head 20 of the working shaft 2. The first plate element 23 is connected to the second ends 412 and 422 of the first 41 and second 42 coil springs.

According to a preferred embodiment of the invention, the spring assembly 4 preferably comprises a first lever 43, which has a main element 44 coaxially mounted on the first subassembly 21 of the working shaft 2 in accordance with the disk 22. The main element 44 of the first lever 43 is traditionally provided with a locking means 441 for the first ends 411, 421 of the first and second coil springs 41, 42. As an example, said fixing means may be formed by a groove in which said first ends 411 and 421 of said first th and second coil springs 41 and 42.

The distal end 45 of the first lever 43 protrudes from the edge of the disk 22 and is connected to the specified first plate element 23 of the first subassembly 21.

According to a particularly preferred embodiment of the drive mechanism 1 of the invention, the first lever 43 comprises adjusting means 46 that are connected to the first plate element 23 for adjusting the preload of the first 41 and second 42 coil springs. Thus, the speed characteristics of the first and second springs 41 and 42 can be varied or at least fine-tuned according to needs, whereby providing an accurate calibration of the speed characteristics of the drive mechanism and / or compensation for changes due to, for example, wear of the spring itself or other mechanical components of the drive mechanism and / or switch. In particular, the regulating means 46 are preferably arranged so as to cooperate with the first plate element 23 of the working shaft 2. In fact, in accordance with this embodiment, the regulating means 46 enable the first lever 40 to rotate (on which the first ends 411 and 421 are fixed the first and second coil springs 41 and 42) relative to the disk 22 of the working shaft 2, whereby changing the preload of the coil springs 41, 42 and, therefore, also their speed characteristics.

By way of example, the adjusting means 40 may comprise a hole, preferably a threaded hole, located at the remote end portion 45 of the first lever 43, and screw means 48 inserted into said hole and abutting against the first plate element 23 of the working shaft 2. Thus, by turning screw 48, the second lever 42 can be rotated to a greater or lesser extent relative to the working shaft 2, therefore, changing the preload applied to the coil springs 41 and 42.

Preferably, the drive shaft 3 comprises a second subassembly 31, comprising a second L-shaped arm 32 having a flat base 33 mounted rotatably along said first longitudinal axis, perpendicular to it; the second plate element 34 projects perpendicularly from the flat base 33 in the direction of the head 20 of the working shaft 2.

In fact, the first 23 and second 34 plate elements protrude, respectively, from the disk 22 and the flat base 33 along parallel directions. Also, the second plate element 34 is located at a distance from the specified first longitudinal axis, which is greater than the distance of the first plate element 23 from the first longitudinal axis; in other words, the length of the flat base 33 is greater than the diameter of the disk 22. Preferably, as shown in FIG. 4, the length of the second plate element 34 is greater than the length of the first plate element 23.

As shown in the accompanying figures, preferably, the second plate element 34 is connectable to the second ends 412 and 422 of the first and second coil springs 41 and 42.

Preferably, the second sub-node 31 of the drive shaft 3 further comprises a main body 35 having a first side surface 36 that is attached to a flat base 33 of the second L-shaped arm 32. The main body 35 has a second side surface, for example parallel and opposite to the first side surface 36 on which the first 51 and second 52 clamping legs are located.

As shown in FIG. 2 and 5-8, in accordance with a preferred embodiment of the drive mechanism 1 of the invention, the clamping means 5 comprises first 53 and second 54 clamping dogs slidably mounted on the third plate 13; the first 53 and second 54 sliding clamping dogs are movable between the clamping position and the position of expansion and are connected, respectively, with the first 51 and second 52 clamping tabs.

Also, according to a particularly preferred embodiment of the drive mechanism 1 of the invention, the first 61 and second 62 release means comprise a first 610 and a second 620 release buttons located in front of the drive mechanism 1.

The operation will be explained in detail with reference to FIG. 5-8, showing a preferred embodiment of the invention.

As shown in the figures, the first 53 and second 54 clamping sliding dogs are slidably mounted in the corresponding groove 530 and 540 in the third plate 13 located between the base 10 and the front 11 of the plates.

In FIG. 5 shows an operating position in which the first and second coil springs 41 and 42 are loaded, and the drive shaft 3 is supported by the clamping means 5 in a position corresponding to the opening position of the contacts of the associated switch.

According to this embodiment, in this position, the first sliding dog 53 is supported in the first clamping position by the first clamping lever 55, in this first clamping position, the first sliding sliding dog 53 abuts the first clamping foot 51.

With reference to FIG. 6, when said first clamping lever 55 has been unclenched, the first clamping sliding dog 53 slides in the groove 530 and moves to the first expansion position, in this first expansion position, the drive shaft 3 freely rotates in the first direction, in this case, counterclockwise relative to the rear view drive mechanism 1.

The drive shaft 3 rotates, transmitting power and energy to the contact system of the associated switch, until it reaches the position in FIG. 7. In this position, the drive shaft 3 is supported by the clamping means 5 in a position corresponding to the position of the contact closure in the associated switch, while one of the two coil springs is unclenched, while the other spring is still loaded.

In the position of FIG. 7, the second clamping sliding dog 54 is supported in the second clamping position by a second clamping lever, which is not shown, as it is obstructed by the third plate 13, but which is similar to the first clamping lever 55. As shown in FIG. 7, in the second clamping position, the second clamping sliding dog 54 abuts against the second clamping tab 52 mounted on the drive shaft 3.

As shown in FIG. 8, when the second clamping lever is unclenched, the second clamping sliding dog 54 slides in the groove 540 and moves to the second expansion position, in this second expansion position, the drive shaft 3 freely rotates in a second direction that is opposite to the indicated first direction, in this case, clockwise arrow relative to the rear view of the drive mechanism 1.

Thus, the drive shaft 3 rotates, transmitting power and energy to the contact system of the associated switch, until it reaches a position corresponding to its position in FIG. 7. In this position, the drive shaft 3 is in a position corresponding to the opening position of the contacts in the associated switch, while both coil springs 41 and 42 are unclenched.

Preferably, the clamping means 5 comprises first 57 and second locking means for locking, respectively, said first 55 and second clamping levers. The second blocking means are not shown, as they are blocked by the third plate 13, but they are similar to the first blocking means 57.

The first locking means 57 may, for example, consist of a pivot pin having a first position (FIG. 5), in which it serves as an obstacle to the first clamping lever 55, blocking it, and a second position (FIG. 6), in which the first clamping lever 55 unclenched. A similar device is also possible for the second locking means and the second clamping lever.

The first 57 and second blocking means are traditionally actuated by the first 610 and second 620 release buttons. The lever system comprises levers 630, 640 and 650, which may be provided for connecting the release button 620 to the associated second locking means. In addition, return springs 550 and 540 may also be provided to facilitate the return of the first 55 and second clamping levers.

In a particularly preferred embodiment of the drive mechanism 1 according to the invention, a second working shaft 9 also takes place. The second working shaft 9 is preferably mounted on a second longitudinal axis parallel to said first longitudinal axis, and can preferably be used to carry out the grounding operation of the switch impact on the shaft, which is independent of the first (main) working shaft 2, which is used for the operation of opening and closing.

As can be seen from the above description, the drive mechanism 1 for the medium voltage circuit breaker, in particular for the medium voltage fuse switch, of the present invention has several advantages with respect to medium voltage circuit breakers equipped with conventional drive mechanisms.

In particular, the opening / closing operation can be easily performed by acting on the push buttons 610 and 620.

In addition, the presence of control means 46 does not require overly precise sizing and preloading of the coil springs 41 and 42, since the speed characteristics of the springs can be calibrated and finely tuned after assembly. Moreover, the regulating means 46 provide the ability to adjust the speed characteristics of the coil springs 41 and 42 in the event of a temporary change in the characteristics of the spring itself and / or associated mechanical components.

It is worth noting that the aforementioned means (i.e., expanding means and regulating means) can be implemented in a relatively simple manner, with a reduced number of constituent elements of a relatively simple structure. Thus, the drive mechanism of the invention is also economically efficient.

In General, the design of the drive mechanism of the invention is very compact and can be adapted, with only a slight change, to a number of different applications of medium voltage.

The drive mechanism for the medium voltage fuse switch of the invention may also contain additional components and means that have not been described in detail since they can be of a traditional form.

Thus designed drive mechanism for a circuit breaker with a medium-voltage fuse can undergo numerous changes and be implemented in several ways that are within the scope of the invention. Moreover, all components described herein may be replaced by other technically equivalent elements. In fact, the components and dimensions of the device can be of any nature, in accordance with the need and the state of the art.

Claims (11)

1. The drive mechanism (1) for a medium voltage fuse switch, comprising:
- the base plate (10) and the front plate (11), forming the inner space containing the working shaft (2) and the drive shaft (3), coaxially mounted along the first longitudinal axis, while the drive shaft (3) is made with the possibility of connection with the kinematic circuit breaker circuit breaker medium voltage for the operation of opening / closing the switch, while the working shaft (2) has a head (20) connected to the control handle for manually actuating the working shaft (2);
- a unit (4) of springs, which contains the first (41) and second (42) coil springs having a first end (411, 421) connected to the working shaft (2), while the coil springs (41, 42) are made with the possibility their loading by turning the working shaft (2) and driving the drive shaft (3) when unclenched, while the first coil spring (41) is configured to rotate the drive shaft (3) in the opposite direction relative to the rotation specified by the second coil spring (42 );
- clamping means (5) for clamping the drive shaft (3), containing the first (51) and second (52) clamping tabs located on the drive shaft (3);
- the first (61) and second (62) expanding means for expanding the drive shaft (3) and allowing it to rotate, while the first expanding means (61) is configured to rotate the drive shaft (3) in the opposite direction relative to the second expansion means ( 62), characterized in that the working shaft (2) contains a first subassembly (21) containing a disk (22) perpendicularly mounted relative to the first longitudinal axis, and further comprising a first plate element (23) protruding perpendicular to the edges of the disk (22) in the direction of the head (20) of the working shaft (2). 2. The drive mechanism (1) according to claim 1, characterized in that the spring assembly (4) comprises a first lever (43) having a main element (44) coaxially mounted on the first subunit (21) of the working shaft (2), and a remote end (45) protruding from the edge of the disk (22), while the main element (44) is provided with fixing means (441) for the first ends (411, 421) of the first and second coil springs (41, 42), while the remote end (45) is connected to the first plate element (23) of the first subassembly (21). 3. The drive mechanism (1) according to claim 2, characterized in that the fixing means (441) comprises a groove in which the first ends (411, 421) of the first and second coil springs (41, 42) are fixed, and further characterized in that that the distal end (45) of the first lever (43) contains regulating means (46) connected to the first plate element (23) for regulating the preload of the first (41) and second (41) coil springs. 4. The drive mechanism (1) according to any one of claims 1 to 3, characterized in that the drive shaft (3) contains a second subassembly (31) containing a second L-shaped lever (32) having a flat base (33) installed with the possibility of rotation along the specified first longitudinal axis, perpendicular to it; and a second plate element (34), perpendicularly protruding from the flat base (33) in the direction of the head (20) of the working shaft (2), while the second subassembly (31) further comprises a main body (35) having a first side surface (36) attached to the flat base (33) of the second L-shaped lever (32), and a second side surface on which the first (51) and second (52) clamping legs are located. 5. The drive mechanism (1) according to claim 4, characterized in that the second plate element (34) is connected to the second ends (412, 422) of the first and second coil springs (41, 42). 6. The drive mechanism (1) according to any one of claims 1 to 3 and 4, characterized in that the clamping means (5) contains the first (53) and second (54) clamping sliding dogs mounted for sliding on the third plate (13 ) and movable between the clamping position and the position of expansion, and associated with the first (51) and second (52) clamping legs. 7. The drive mechanism (1) according to claim 6, characterized in that the first (53) and second (54) clamping sliding dogs are slidably mounted in the corresponding groove (530, 540) in the third plate (13), while the first the sliding dog (53) is supported in the first clamping position by the first clamping lever (55), in this first clamping position, the first clamping sliding dog (53) abuts the first clamping foot (51), while the first clamping sliding dog (53) moves to the first unclenching position when the first the expanding lever (55) is expanded, in this first expansion position, the drive shaft (3) rotates freely in the first direction, while the second clamping sliding dog (54) is supported in the second clamping position by the second clamping lever, in this second clamping position, the second clamping sliding the dog (54) abuts against the second clamping foot (52), while the second clamping sliding dog (54) moves to the second expansion position when the second expansion lever is unclenched, in such a second position zhimaniya drive shaft (3) freely rotates in a second direction opposite said first direction. 8. The drive mechanism (1) according to claim 7, characterized in that the clamping means (5) comprises first (57) and second locking means for locking, respectively, the first (55) and second (56) clamping levers. 9. The drive mechanism (1) according to any one of claims 1 to 3, 6, 7 and 8, characterized in that the first (61) and second (62) expanding means comprise a first (610) and a second (620) expansion button, located in front of the drive mechanism (1). 10. The drive mechanism (1) according to claim 9, characterized in that the first (610) and second (620) release buttons, respectively, affect the first (57) and second blocking means. 11. A medium voltage fuse switch, characterized in that it comprises a drive mechanism (1) according to any one of claims 1 to 10.

Images